Hydraulic interrupter safety system and method

ABSTRACT

A system and method for interrupting a Global Navigation Satellite System (GNSS)-based automatic steering mode of a hydraulic steering system on a vehicle. When a steering wheel is manually turned by an operator, pressurized hydraulic fluid from a steering directional control valve activates an interrupter having an interrupter valve. The interrupter valve blocks pressurized fluid flow to the automatic steering system, thus overriding automatic steering and giving the operator full manual steering control via the steering wheel. The hydraulic interrupt system is mechanical with no electronic elements.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority in U.S. Provisional Patent Application No. 61/919,366, filed Dec. 20, 2013, which is incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to vehicle steering, and in particular to a hydraulic safety interrupter for automatic steering (“autosteer”) systems, which can use sensors including Global Navigation Satellite System (GNSS), and other guidance and navigation receivers and equipment.

2. Description of the Related Art

A. GNSS-Based Vehicle Guidance Background

The use of sensors for automating vehicle guidance and machine control has significantly advanced these fields and enabled a number of applications, including many in agriculture, transportation and other industries. For example and without limitation, GNSSs are commonly used for guidance, navigation and machine control. GNSSs include the Global Positioning System (GPS) and other satellite-based systems. Various GNSS receivers are available for aviation, marine and terrestrial vehicles. The GNSS information provided by such receivers can be processed and used for navigation. In more sophisticated systems, vehicle guidance can be automatically controlled using such information. For example, a predetermined travel or flight path can be programmed into an on-board computer. The vehicle guidance system can automatically maintain appropriate course parameters, such as course, heading, speed, altitude, end-of-row U-turns, etc. Control system, feedback theory, and signal filtering techniques can be used to interactively anticipate (with higher order systems) and compensate for course deviations and navigation errors. Such sophisticated autopilot and automatic steering systems tend to involve powerful computers and complex flight and steering controls integrated with manual controls.

Accurate vehicle guidance and equipment control are important objectives in agricultural operations generally and agricultural equipment specifically. For example, cultivating, tilling, planting, spraying, fertilizing, harvesting and other farming operations typically involve specialized equipment and materials, which are operated and applied by making multiple passes over cultivated fields. Ideally, the equipment is guided through accurately-spaced passes or swaths, the spacing of which is determined by the swath width of the equipment.

GNSS technology advanced the field of agricultural guidance by enabling reliable, accurate systems which are relatively easy to use. GNSS guidance systems are adapted for displaying directional guidance information to assist operators with manually steering the vehicles. For example, the Outback steering guidance product line was developed primarily for agricultural applications. Current GNSS-based products include the Outback S3, the eDrive TC and the eDrive X™ which are available from Outback Guidance (www.outbackguidance.com) and are manufactured by AgJunction, Inc. (www.agjunction.com) of Hiawatha, Kans. These products are covered by U.S. Pat. No. 6,539,303 and No. 6,711,501, which are incorporated herein by reference. They include on-board computers which can be programmed for steering vehicles through various straight-line and curved (“contour”) patterns. An advantage of this system is its ability to retain field-specific cultivating, planting, spraying, fertilizing, harvesting and other patterns in memory. This feature enables operators to accurately retrace such patterns. Another advantage relates to the ability to interrupt operations for subsequent resumption by referring to system-generated logs of previously treated areas.

The OUTBACK S™ GNSS guidance system provides the equipment operators with real-time visual indications of heading error with a steering guide display and crosstrack error with a current position display. They respectively provide steering correction information and an indication of the equipment position relative to a predetermined course. Operators can accurately drive patterns in various weather and light conditions, including nighttime, by concentrating primarily on such visual displays. Significant improvements in steering accuracy and complete field coverage are possible with this system.

Another type of GNSS vehicle guidance equipment automatically steers the vehicle along all or part of its travel path and can also control an agricultural procedure or operation, such as spraying, planting, tilling, harvesting, etc. Examples of such equipment are shown in U.S. Pat. No. 7,142,956, which is incorporated herein by reference. U.S. Pat. No. 7,437,230 shows satellite-based vehicle guidance control in straight and contour modes, and is also incorporated herein by reference.

GNSS guidance systems and equipment are distinguished by their vehicle path configuration capabilities. Initially, straight-line AB (i.e., between points A and B) guidance consists of multiple, parallel straight lines, which are separated by the swath widths of the vehicles. Straight line AB guidance is ideally suited for rectangular fields and continuously-repeating, parallel swathing.

Non-rectangular and terraced fields typically require curvilinear vehicle paths that follow the field perimeters and the terraced elevation contours. Contour guidance systems and methods were developed to accommodate such field conditions using GNSS coordinates to define curvilinear vehicle paths. See, for example, Korver U.S. Pat. No. 5,928,309. GNSS positions can be logged on-the-fly at intervals of, for example, 0.20 seconds. Contour guidance can be accomplished by computer-generating each subsequent pass from the GNSS-defined previous pass and a user-entered swath width.

Another type of GNSS contour guidance equipment outputs guidance signals relative to the edges of all previously logged swaths. Such logged swaths typically correspond to field areas where operations, e.g. spraying, have already been carried out. See, for example, U.S. Pat. No. 6,539,303 and No. 6,711,501, which are assigned to a common assignee herewith and are incorporated herein by reference.

Automatic steering accommodates “hands-off” operation, taking into account vehicle operating parameters, such as turning radii, speeds, swath widths, etc. Appropriate machine control functions, such as implement steering and spray boom control, can also be automated.

B. Manual-Automatic Steering Interface

Although agricultural operations have utilized robotic equipment without human operators on-board, standard practice is to provide an operator with the ability to override the automatic steering system. For example, some automatic steering systems will disengage when operator input, e.g., via steering wheel, is sensed. On-board computers can detect such manual turning inputs and issue appropriate output commands for disengaging auto-steering functions. GNSS-guided automatic steering can be accomplished with hydraulic valve blocks retrofit on existing vehicles, or installed as original equipment in new vehicles. GNSS receivers provide positioning and navigation data, which can be processed by on-board microprocessors for steering and other vehicle control functions. An advantage of the present invention is to provide a hydraulic steering interrupter which is manually-activated and is independent of the automated, computerized steering controls. Heretofore there has not been available a hydraulic steering interrupter with the advantages and features of the present invention.

SUMMARY OF THE INVENTION

In the practice of the present invention, an interrupter is provided for a hydraulic steering system on a vehicle, which can utilize GNSS-based auto steering. The interrupter is preferably positioned upstream of an auto-steering hydraulic valve block, and activates automatically when a steering wheel is manually turned by the operator. The interrupter senses a pressure signal from the vehicle manual steering and interrupts (i.e., blocks) pressurized hydraulic fluid flow to the automatic steering input valve, thus canceling the automatic steering command and giving the operator full manual steering control via the steering wheel.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a vehicle, such as a tractor, equipped with a hydraulic interrupter in a GNSS-based automatic steering system, embodying an aspect of the present invention.

FIG. 2 is a block diagram of a closed center steering system including a hydraulic interrupter embodying an aspect of the present invention.

FIG. 3 is a block diagram of an open center steering system including a hydraulic interrupter comprising an alternative aspect of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS I. Introduction and Environment

As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention, which may be embodied in various forms. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present invention in virtually any appropriately detailed structure.

Certain terminology will be used in the following description for convenience in reference only and will not be limiting. For example, up, down, front, back, right and left refer to the invention as oriented in the view being referred to. The words “inwardly” and “outwardly” refer to directions toward and away from, respectively, the geometric center of the embodiment being described and designated parts thereof Said terminology will include the words specifically mentioned, derivatives thereof and words of similar meaning.

Without limitation on the generality of useful applications of the present invention, a hydraulic interrupter 21 is provided in a steering control system 2 on a vehicle 1, which can comprise a tractor equipped with a Global Navigation Satellite System (GNSS) 13. The GNSS system 13 includes a receiver 5 which can be connected to a pair of antennas 9 for vector directional guidance in a horizontal plane based on differencing the signals received at the respective antennas 9. Such directional guidance techniques are used for obtaining a vehicle heading in an X-Y (horizontal) plane, even with the vehicle stationary. A guidance central processing unit (CPU) 7 is connected to the receiver 5 for processing the GNSS positioning signals and outputting guidance signals to the steering control system 2 for auto-steering the vehicle 1. The vehicle 1 can also be equipped with a tow-behind implement, which can also be provided with GNSS-based control interfacing with the vehicle steering control system 2. For example, implement-steering can provide advantages in certain agricultural and other operations.

II. Closed Center Embodiment Steering Control System 2

The steering control system 2 embodying the present invention can be installed in various vehicles with manual controls, such as a steering wheel 8, and an electric-hydraulic power steering subsystem 4 for assisting manual steering and for primarily steering the vehicle in automatic guidance operating modes (i.e., “auto-steer”). The electric-hydraulic steering subsystem 4 is adapted for coupling to a guidance system, such as the GNSS-based guidance system 13 described above. The steering subsystem 4 includes a hydraulic interrupter 21 with an interrupter valve 22 adapted for manually overriding or interrupting the electric-hydraulic steering subsystem 4 and returning control to an operator via the steering wheel 8. The power steering subsystem 4 can be hydraulic, electric-over-hydraulic, pneumatic, etc.

The steering control system 2 includes a steering directional control valve 6 connected to the steering wheel 8. A steering priority valve 10 connects the steering directional control valve 6 to a pump 11 mounted on the vehicle 1. In an embodiment of the present invention, the steering directional control valve 6 has a “closed center” configuration (FIG. 2). A load sense line 15 extends from the steering directional control valve 6 to a load sense shuttle valve 24 and the steering priority valve 10 via a “T” connection 25. The load sense line 15 activates the interrupter valve 22 by detecting or “sensing” greater hydraulic pressure from the steering directional control valve 6 signaling an operator turning a steering wheel 8 and thus manually taking over the vehicle steering. An “override” condition thus occurs, interrupting the automatic steering operation by interrupting the hydraulic fluid flow to the proportional flow control directional valve 18.

Hydraulic lines 12 connect the steering directional control valve 6 to respective right and left load holding valves 14R, 14L, which are adapted for maintaining certain fluid pressure levels in the electric-hydraulic power steering subsystem 4. The system 4 steers the vehicle 1 via a double-acting hydraulic cylinder 28, which can link directly to the vehicle steering gear. A shuttle valve 16 is positioned between the load holding valves 14R, 14L. A proportional flow control directional valve 18 receives a constant flow of hydraulic fluid via a pressure compensating valve 20. The pressure drop across the compensating valve 20 is maintained relatively constant. The interrupter valve 22 is located between the pressure compensating valve 20 and an enabling valve 26, which is solenoid-activated by the GNSS-based steering subsystem 4. The interrupter valve 22 is spring-loaded for maintaining an open position until an override closes it or blocks pressure flow to the auto-steering subsystem 4. Such an override signal originates with the steering priority valve 10 at the T connect 25, which acts on a load sense shuttle valve 24. The load sense shuttle valve 24 provides an input to the pump 11 for varying the displacement as necessary to accommodate the steering system loads. For example, in the configuration shown, the load sense shuttle ball would move to the right (FIG. 2) for manual steering. In an automatic steering mode (i.e., enable valve 26 open), the ball would be in the left position. Hydraulic fluid is pumped from and returned to a tank 17 having a check valve 29.

III. Open-Center Alternative Embodiment Steering Control System 102 (FIG. 3)

An open-center steering control system 102 comprising an alternative embodiment of the present invention is shown in FIG. 3. The open center hydraulic circuit utilizes a continuous flow of hydraulic fluid, which is returned to the tank 117 through an “open center” of a steering directional control valve 106 connected to and controlled by a steering wheel 108. The control system 102 includes an auto-steer subsystem 104, a steering priority valve 110, a pump 111, and hydraulic lines 112, which have similar functions to the corresponding components described above. An interrupter valve 122 is provided for interrupting the fluid flow like the interrupter valve 22 described above. A “T” connector 125 supplies fluid to a pressure compensating valve 120. An enable valve 126 connects to the interrupter valve 122. A hydraulic interrupter 121 comprises the interrupter valve 122 and other components connected thereto for interrupting pressure flow to the auto-steer subsystem 104 when the steering wheel 108 is moved. A check valve 129 extends between lines connecting a pressure side of the circuit and a return to the tank 117. Excess flow EF from the hydraulic interrupter valve 122, which occurs because of the open center configuration, can be returned to the tank 117.

The system 102 also includes left and right load holding valves 114L, 114R, which connect to respective sides of the steering piston-and-cylinder unit 128. A shuttle valve 116 connects the fluid inlet sides of the load holding valves 114L, 114R. A proportional flow control valve 118 is connected to the load holding valves 114L, 114R and to a directional valve 123.

IV. CONCLUSION

It is to be understood that the invention can be embodied in various forms, and is not to be limited to the examples discussed above. Other components can be utilized. For example, various other types of sensor systems can be utilized in conjunction with hydraulic systems with the advantages and features of the hydraulic interrupter valve discussed above. 

Having thus described the invention, what is claimed as new and desired to be secured by Letters Patent is:
 1. A steering interrupt system for a vehicle, which vehicle includes steerable wheels, a hydraulic steering system with a pressurized fluid source selectively connected to the steerable wheels, a steering directional control valve connected to the pressurized fluid source, a steering wheel connected to the steering directional control valve, a steering actuator selectively connected to the pressurized fluid source via the steering directional control valve and the steerable wheels, and an automatic steering system connected to and automatically controlling the steering actuator in an automatic steering mode, which steering interrupt system includes: said steering interrupt system configured for switching from said automatic steering mode to an interrupt mode when said steering wheel is turned by an operator; an interrupt valve connected to said steering directional control valve and configured for interrupting pressurized fluid flow to said steering actuator in said interrupt mode; said steering directional control valve being connected to said steering actuator in said interrupt mode; said steering directional control valve providing pressurized hydraulic fluid to said steering actuator in said interrupt mode and thereby controlling said steerable wheels in proportion to movement of said steering wheel by said operator; and said interrupt system configured for switching from said interrupt mode to said automatic steering mode when said steering wheel is released by said operator.
 2. The steering interrupt system according to claim 1, wherein said automatic steering system includes a Global Navigation Satellite System (GNSS)-based positioning system connected to said steering actuator.
 3. The steering interrupt system according to claim 1, wherein said steering actuator includes a piston-and-cylinder unit.
 4. The steering interrupt system according to claim 1, wherein said hydraulic steering system is a closed center hydraulic circuit.
 5. The steering interrupt system according to claim 1, wherein said hydraulic steering system is an open center hydraulic circuit.
 6. The steering interrupt system according to claim 1, wherein: said interrupt valve is spring-loaded; the spring of said interrupt valve is configured to expand in said automatic steering mode maintaining an open position allowing fluid to flow therethrough; and said spring of said interrupt valve is configured to compress in said interrupt mode, closing said interrupt valve and blocking fluid flow.
 7. The steering interrupt system according to claim 1, wherein said hydraulic steering system further comprises: said pressurized fluid source including a pump; a steering priority valve selectively connecting said pump and said steering directional control valve; a solenoid-actuated valve connected to said pressurized fluid source and activated by said automatic steering system; a pressure-compensating valve connected to said pressurized fluid source; a proportional flow control directional valve connected to said pressurized fluid source and operated by said automatic steering system; a pair of load-holding valves connected to said proportional flow control directional valve and said steering actuator; and a shuttle valve connected to said load-holding valves and said proportional flow control directional valve.
 8. The steering interrupt system according to claim 4, wherein said hydraulic steering system further comprises: a load sensor connected to said steering directional control valve, a load sense shuttle valve, and said interrupt valve; said load sensor configured for sensing a fluid pressure load resulting from said operator turning said steering wheel; and said interrupt valve configured for closing in response to said sensed fluid pressure load by said load sensor.
 9. The steering interrupt system according to claim 5, wherein said hydraulic steering system further comprises: a directional valve connected to said pressurized fluid source; a fluid tank; and an excess flow line configured for selectively diverting excess pressurized fluid to said fluid tank.
 10. A hydraulic steering system for a vehicle including steerable wheels, which steering system includes: a pressurized fluid source selectively connected to said steerable wheels; a steering directional control valve connected to said pressurized fluid source; a steering wheel connected to said steering directional control valve; a steering actuator selectively connected to said pressurized fluid source via said steering directional control valve and said steerable wheels; an automatic steering mode configured for automatically controlling said steering actuator with said pressurized fluid source; an interrupt mode configured for overriding said automatic steering mode in response to said steering wheel being turned by an operator; an interrupt valve connected to said pressurized fluid source and said steering directional control valve and configured for blocking pressurized fluid flow to said steering actuator in said interrupt mode; said steering directional control valve being connected to said steering actuator in said interrupt mode; said steering wheel configured for controlling said steerable wheels via said steering directional control valve and said steering actuator in said interrupt mode; and said hydraulic steering system configured for switching from said interrupt mode to said automatic steering mode when said steering wheel is released by said operator.
 11. The hydraulic steering system according to claim 10, further comprising: a Global Navigation Satellite System (GNSS)-based positioning system connected to said steering actuator; and wherein said automatic steering mode is controlled by said GNSS-based positioning system.
 12. The hydraulic steering system according to claim 10, wherein said steering actuator includes a piston-and-cylinder unit.
 13. The hydraulic steering system according to claim 10, further comprising a closed center hydraulic circuit.
 14. The hydraulic steering system according to claim 10, further comprising an open center hydraulic circuit.
 15. The hydraulic steering system according to claim 10, wherein: said interrupt valve is spring-loaded; the spring of said spring-loaded interrupt valve is configured to expand in said automatic steering mode maintaining an open position allowing fluid to flow therethrough; and said spring of said spring-loaded interrupt valve is configured to compress in said interrupt mode, closing said spring-loaded interrupt valve and blocking fluid flow.
 16. The hydraulic steering system according to claim 10, further comprising: said pressurized fluid source including a pump; a steering priority valve selectively connecting said pump and said steering directional control valve; a solenoid-actuated valve connected to said pressurized fluid source and activated in said automatic steering mode; a pressure-compensating valve connected to said pressurized fluid source; a proportional flow control directional valve connected to said pressurized fluid source and operated in said automatic steering mode; a pair of load-holding valves connected to said proportional flow control directional valve and said steering actuator; and a shuttle valve connected to said load-holding valves and said proportional flow control directional valve.
 17. The hydraulic steering system according to claim 13, further comprising: a load sensor connected to said steering directional control valve, a load sense shuttle valve, and said interrupt valve; said load sensor configured for sensing a fluid pressure load resulting from said operator turning said steering wheel; and said interrupt valve configured for closing in response to said sensed fluid pressure load by said load sensor.
 18. The hydraulic steering system according to claim 14, further comprising: a directional valve connected to said pressurized fluid source; a fluid tank; and an excess flow line configured for selectively diverting excess pressurized fluid to said fluid tank.
 19. A hydraulic steering system for a vehicle including steerable wheels, which steering system includes: a pressurized fluid source selectively connected to said steerable wheels; a steering directional control valve connected to said pressurized fluid source; a steering wheel connected to said steering directional control valve; a steering actuator selectively connected to said pressurized fluid source via said steering directional control valve and said steerable wheels; an automatic steering mode configured for automatically controlling said steering actuator with said pressurized fluid source; an interrupt mode configured for blocking fluid flow and overriding said automatic steering mode in response to said steering wheel being turned by an operator; an interrupt valve connected to said pressurized fluid source and said steering directional control valve and configured for blocking pressurized fluid flow to said steering actuator in said interrupt mode; said steering directional control valve being connected to said steering actuator in said interrupt mode; said steering wheel configured for controlling said steerable wheels via said steering directional control valve and said steering actuator in said interrupt mode; said hydraulic steering system configured for switching from said interrupt mode to said automatic steering mode when said steering wheel is released by said operator; a Global Navigation Satellite System (GNSS)-based positioning system connected to said steering actuator; wherein said automatic steering mode is controlled by said GNSS-based positioning system; wherein said steering actuator includes a piston-and-cylinder unit; wherein said interrupt valve is spring-loaded; wherein the spring of said spring-loaded interrupt valve is configured to expand in said automatic steering mode maintaining an open position allowing fluid to flow therethrough; wherein said spring of said spring-loaded interrupt valve is configured to compress in said interrupt mode, closing said spring-loaded interrupt valve and blocking fluid flow; said pressurized fluid source including a pump; a steering priority valve selectively connecting said pump and said steering directional control valve; a solenoid-actuated valve connected to said pressurized fluid source and activated in said automatic steering mode; a pressure-compensating valve connected to said pressurized fluid source; a proportional flow control directional valve connected to said pressurized fluid source and operated in said automatic steering mode; a pair of load-holding valves connected to said proportional flow control directional valve and said steering actuator; and a shuttle valve connected to said load-holding valves and said proportional flow control directional valve.
 20. The hydraulic steering system according to claim 19, further comprising a closed center hydraulic circuit including: a load sensor connected to said steering directional control valve, a load sense shuttle valve, and said interrupt valve, said load sensor configured for sensing a fluid pressure load resulting from said operator turning said steering wheel; and said interrupt valve configured for closing in response to said sensed fluid pressure load by said load sensor.
 21. The hydraulic steering system according to claim 19, further comprising an open center hydraulic circuit including: a directional valve connected to said pressurized fluid source; a fluid tank; and an excess flow line configured for selectively diverting excess pressurized fluid to said fluid tank.
 22. A method of interrupting automatic steering of a vehicle including steerable wheels, a hydraulic steering system with a pressurized fluid source selectively connected to the steerable wheels, a steering directional control valve connected to the pressurized fluid source, a steering wheel connected to the steering directional control valve, a steering actuator selectively connected to the pressurized fluid source via the steering directional control valve and the steerable wheels, an automatic steering system connected to and automatically controlling the steering actuator in an automatic steering mode, an interrupt valve connected to the steering directional control valve and configured for blocking fluid flow and overriding the automatic steering mode in an interrupt mode, and the steering directional control valve being connected to the steering actuator in said interrupt mode, which method comprises the steps of: an operator turning said steering wheel; pressurized fluid from said steering directional control valve closing said interrupt valve, triggering said interrupt mode; said interrupt valve in closed position blocking pressurized fluid flow from said automatic steering system; said steering directional control valve directing pressurized fluid to said steering actuator controlling said steerable wheels in proportion to movement of said steering wheel by said operator; said operator releasing said steering wheel; said interrupt valve opening, allowing fluid flow from said automatic steering system, triggering said automatic steering mode; and said automatic steering system automatically controlling said steering actuator in said automatic steering mode.
 23. The method according to claim 22, wherein said automatic steering system includes a Global Navigation Satellite System (GNSS)-based positioning system connected to said steering actuator.
 24. The method according to claim 22, wherein said steering actuator includes a piston-and-cylinder unit.
 25. The method according to claim 22, wherein said hydraulic steering system is a closed center hydraulic circuit.
 26. The method according to claim 22, wherein said hydraulic steering system is an open center hydraulic circuit.
 27. The method according to claim 22, wherein said hydraulic steering system further comprises: said pressurized fluid source including a pump; a steering priority valve selectively connecting said pump and said steering directional control valve; a solenoid-actuated valve connected to said pressurized fluid source and activated by said automatic steering system; a pressure-compensating valve connected to said pressurized fluid source; a proportional flow control directional valve connected to said pressurized fluid source and operated by said automatic steering system; a pair of load-holding valves connected to said proportional flow control directional valve and said steering actuator; a shuttle valve connected to said load-holding valves and said proportional flow control directional valve; and wherein said interrupt valve is spring-loaded.
 28. The method according to claim 27, the method further comprises: the spring of said spring-loaded interrupt valve compressing, closing said interrupt valve in said interrupt mode; said pump displacing said pressurized fluid through said steering directional control valve; said steering priority valve sending an override signal to said hydraulic steering system in said interrupt mode; said spring of said spring-loaded interrupt valve expanding, opening said interrupt valve in said automatic steering mode; said solenoid-actuated valve controlling pressurized fluid flow in said automatic steering mode as directed by said automatic steering system; said pressure-compensating valve maintaining fluid flow pressure; said proportional flow control directional valve controlling the directional flow of said pressurized fluid to said load-holding valves as directed by said automatic steering system; said load-holding valves controlling pressurized fluid flow to said steering actuator; and said shuttle valve preventing backflow of fluid from said load-holding valves back to said proportional flow control directional valve.
 29. The method according to claim 25, wherein the hydraulic steering system further comprises: a load sensor connected to said steering directional control valve, a load sense shuttle valve, and said interrupt valve, said load sensor configured for sensing a fluid pressure load resulting from said operator turning said steering wheel; and said interrupt valve configured for closing in response to said sensed fluid pressure load by said load sensor.
 30. The method according to claim 29, the method further comprises: said load sensor sensing a fluid pressure load resulting from said operator turning said steering wheel; said interrupt valve closing in response to said sensed fluid pressure load by said load sensor; and said load sense shuttle valve triggering a change in fluid flow pressure and preventing pressurized fluid flow to said automatic steering system in said interrupt mode.
 31. The method according to claim 26, wherein the hydraulic steering system further comprises: a directional valve connected to said pressurized fluid source; a fluid tank; and an excess flow line configured for selectively diverting excess pressurized fluid to said fluid tank.
 32. The method according to claim 31, the method further comprises: said directional valve maintaining pressurized fluid flow in the proper direction; and said excess flow line diverting excess fluid from said hydraulic steering system to said fluid tank. 